Your search keyword '"Condon, Samuel S."' showing total 4 results

1. No longer impossible: the self-lensing binary KIC 8145411 is a triple

Author

Yamaguchi, Natsuko, El-Badry, Kareem, Ciardi, David R., Latham, David W., Masuda, Kento, Bieryla, Allyson, Clark, Catherine A., and Condon, Samuel S.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Five self-lensing binaries (SLBs) have been discovered with data from the \textit{Kepler} mission. One of these systems is KIC 8145411, which was reported to host an extremely low mass (ELM; $0.2\,M_{\odot}$) white dwarf (WD) in a 456-day orbit with a solar-type companion. The system has been dubbed "impossible", because evolutionary models predict that $\sim 0.2\,M_{\odot}$ WDs should only be found in tight orbits ($P_{\rm orb} \lesssim$ days). In this work, we show that KIC 8145411 is in fact a hierarchical triple system: it contains a WD orbiting a solar-type star, with another solar-type star $\sim 700\,$AU away. The wide companion was unresolved in the Kepler light curves, was just barely resolved in Gaia DR3, and is resolved beyond any doubt by high-resolution imaging. We show that the presence of this tertiary confounded previous mass measurements of the WD for two reason: it dilutes the amplitude of the self-lensing pulses, and it reduces the apparent radial velocity (RV) variability amplitude of the WD's companion due to line blending. By jointly fitting the system's light curves, RVs, and multi-band photometry using a model with two luminous stars, we obtain a revised WD mass of $(0.53 \pm 0.01)\,M_{\odot}$. Both luminous stars are near the end of their main-sequence evolution. The WD is thus not an ELM WD, and the system does not suffer the previously proposed challenges to its formation history. Similar to the other SLBs and the population of astrometric WD binaries recently identified from Gaia data, KIC 8145411 has parameters in tension with standard expectations for formation through both stable and unstable mass transfer. The system's properties are likely best understood as a result of unstable mass transfer from an AGB star donor., Comment: 16 pages, 13 figures, Published in PASP

Published

2024

2. Cryogenic Focus Measurement System for a Wide-Field Infrared Space Telescope

Author

Condon, Samuel S., Padin, Stephen, Bock, James, Hui, Howard, Korngut, Phillip, Nguyen, Chi, and Otsby, Jordan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Optics

Abstract

We describe a technique for measuring focus errors in a cryogenic, wide-field, near-infrared space telescope. The measurements are made with a collimator looking through a large vacuum window, with a reflective cold filter to reduce background thermal infrared loading on the detectors and optics. The vacuum window and cold filter introduce wavefront error which we characterize using an autocollimating microscope. For the $200\textrm{ mm}$ diameter aperture $f/3$ space telescope, SPHEREx, we achieve a focus position measurement with a $\sim15 \textrm{ }\mu \textrm{m systematic}$ and a $\sim 5\textrm{ }\mu \textrm{m statistical}$ error., Comment: 9 pages, 14 figures, submission to Applied Optics

Published

2023

3. The SPHEREx instrument optical integration and testing campaign overview

Author

Coyle, Laura E., Matsuura, Shuji, Perrin, Marshall D., Korngut, Phillip M., Bock, James J., Condon, Samuel S., Dowell, Charles D., Hui, Howard, Jeong, Woong-Seob, Jo, Youngsoo, Manatt, Ken, Nguyen, Chi, Nguyen, Hien, Padin, Stephen, Park, Sung-Joon, Pyo, Jeonghyun, and Yang, Yujin

Published

2024

4. Cryogenic focus measurement system for a wide-field infrared space telescope.

Author

Condon SS, Padin S, Bock J, Hui H, Korngut P, Nguyen C, and Ostby J

Abstract

We describe a technique for measuring focus errors in a cryogenic, wide-field, near-infrared space telescope. The measurements are made with a collimator looking through a large vacuum window, with a reflective cold filter to reduce the background thermal infrared loading on the detectors and optics. The vacuum window and cold filter introduce a wavefront error that we characterize using an autocollimating microscope. For the 200 mm diameter aperture f /3 space telescope SPHEREx, we achieve a focus position measurement with a ∼15µ m systematic and a ∼5µ m statistical error.

Published

2024